Mars rock touched by NASA Curiosity has surprises

This image shows where NASA's Curiosity rover aimed two different instruments to study a rock known as "Jake Matijevic." The red dots are where the Chemistry and Camera (ChemCam) instrument zapped it with its laser September 21, 2012, and September24, 2012, which were the 45th and 48th sol, or martian day of operations. The circular black and white images were taken by ChemCam to look for the pits produced by the laser. The purple circles indicate where the Alpha Particle X-ray Spectrometer trained its view. // Credit: NASA/JPL-Caltech/MSSS

The first martian rock NASA’s Curiosity rover has reached out to touch presents a more varied composition than expected from previous missions. The rock also resembles some unusual rocks from Earth’s interior.

The rover team used two instruments on Curiosity to study the chemical makeup of the football-sized rock called Jake Matijevic (matt-EE-oh-vick). The results support some surprising recent measurements and provide an example of why identifying rock composition is such a major emphasis of the mission. Rock compositions tell stories about unseen environments and planetary processes.

“This rock is a close match in chemical composition to an unusual but well-known type of igneous rock found in many volcanic provinces on Earth,” said Edward Stolper of the California Institute of Technology in Pasadena. “With only one martian rock of this type, it is difficult to know whether the same processes were involved, but it is a reasonable place to start thinking about its origin.”

On Earth, rocks with composition like the Jake rock typically come from processes in the planet’s mantle beneath the crust from crystallization of relatively water-rich magma at elevated pressure.

Jake was the first rock analyzed by the rover’s arm-mounted Alpha Particle X-Ray Spectrometer (APXS) instrument and about the 30th rock examined by the Chemistry and Camera (ChemCam) instrument. Two penny-sized spots on Jake were analyzed September 22 by the rover’s improved and faster version of earlier APXS devices on all previous Mars rovers, which have examined hundreds of rocks. That information has provided scientists a library of comparisons for what Curiosity sees.

“Jake is kind of an odd martian rock,” said Ralf Gellert of the University of Guelph in Ontario, Canada. “It’s high in elements consistent with the mineral feldspar, and low in magnesium and iron.”

ChemCam found unique compositions at each of 14 target points on the rock, hitting different mineral grains within it. “ChemCam had been seeing compositions suggestive of feldspar since August, and we’re getting closer to confirming that now with APXS data, although there are additional tests to be done,” said Roger Wiens of Los Alamos National Laboratory in New Mexico.

Examination of Jake included the first comparison on Mars between APXS results and results from checking the same rock with ChemCam, which shoots laser pulses from the top of the rover’s mast.

The wealth of information from the two instruments checking chemical elements in the same rock is just a preview. Curiosity also carries analytical laboratories inside the rover to provide other composition information about powder samples from rocks and soil. The mission is progressing toward getting the first soil sample into those analytical instruments during a “sol,” or martian day.

“Yestersol, we used Curiosity’s first perfectly scooped sample for cleaning the interior surfaces of our 150-micron-sample-processing chambers. It’s our version of a martian carwash,” said Chris Roumeliotis from NASA’s Jet Propulsion Laboratory (JPL) in Pasadena, California.

Before proceeding, the team carefully studied the material for scooping at a sandy patch called “Rocknest,” where Curiosity is spending about three weeks. “That first sample was perfect, just the right particle-size distribution,” said Luther Beegle of JPL. “We had a lot of steps to be sure it was safe to go through with the scooping and cleaning.”

Following the work at Rocknest, the rover team plans to drive Curiosity about 100 yards eastward and select a rock in that area as the first target for using the drill.

During a two-year prime mission, researchers will use Curiosity’s 10 instruments to assess whether the study area ever has offered environmental conditions favorable for microbial life.

The first martian rock NASA’s Curiosity rover has reached out to touch presents a more varied composition than expected from previous missions. The rock also resembles some unusual rocks from Earth’s interior.

The rover team used two instruments on Curiosity to study the chemical makeup of the football-sized rock called Jake Matijevic (matt-EE-oh-vick). The results support some surprising recent measurements and provide an example of why identifying rock composition is such a major emphasis of the mission. Rock compositions tell stories about unseen environments and planetary processes.

“This rock is a close match in chemical composition to an unusual but well-known type of igneous rock found in many volcanic provinces on Earth,” said Edward Stolper of the California Institute of Technology in Pasadena. “With only one martian rock of this type, it is difficult to know whether the same processes were involved, but it is a reasonable place to start thinking about its origin.”

On Earth, rocks with composition like the Jake rock typically come from processes in the planet’s mantle beneath the crust from crystallization of relatively water-rich magma at elevated pressure.

Jake was the first rock analyzed by the rover’s arm-mounted Alpha Particle X-Ray Spectrometer (APXS) instrument and about the 30th rock examined by the Chemistry and Camera (ChemCam) instrument. Two penny-sized spots on Jake were analyzed September 22 by the rover’s improved and faster version of earlier APXS devices on all previous Mars rovers, which have examined hundreds of rocks. That information has provided scientists a library of comparisons for what Curiosity sees.

“Jake is kind of an odd martian rock,” said Ralf Gellert of the University of Guelph in Ontario, Canada. “It’s high in elements consistent with the mineral feldspar, and low in magnesium and iron.”

ChemCam found unique compositions at each of 14 target points on the rock, hitting different mineral grains within it. “ChemCam had been seeing compositions suggestive of feldspar since August, and we’re getting closer to confirming that now with APXS data, although there are additional tests to be done,” said Roger Wiens of Los Alamos National Laboratory in New Mexico.

Examination of Jake included the first comparison on Mars between APXS results and results from checking the same rock with ChemCam, which shoots laser pulses from the top of the rover’s mast.

The wealth of information from the two instruments checking chemical elements in the same rock is just a preview. Curiosity also carries analytical laboratories inside the rover to provide other composition information about powder samples from rocks and soil. The mission is progressing toward getting the first soil sample into those analytical instruments during a “sol,” or martian day.

“Yestersol, we used Curiosity’s first perfectly scooped sample for cleaning the interior surfaces of our 150-micron-sample-processing chambers. It’s our version of a martian carwash,” said Chris Roumeliotis from NASA’s Jet Propulsion Laboratory (JPL) in Pasadena, California.

Before proceeding, the team carefully studied the material for scooping at a sandy patch called “Rocknest,” where Curiosity is spending about three weeks. “That first sample was perfect, just the right particle-size distribution,” said Luther Beegle of JPL. “We had a lot of steps to be sure it was safe to go through with the scooping and cleaning.”

Following the work at Rocknest, the rover team plans to drive Curiosity about 100 yards eastward and select a rock in that area as the first target for using the drill.

During a two-year prime mission, researchers will use Curiosity’s 10 instruments to assess whether the study area ever has offered environmental conditions favorable for microbial life.